Apparatus for removably receiving an end effector for performing surgical operations

ABSTRACT

A surgical instrument apparatus for removably receiving an end effector coupled to an elongate control link for actuating the end effector to perform surgical operations is disclosed. The apparatus includes an actuator housing and an elongate shaft extending from the actuator housing and having a bore for receiving the control link. The apparatus also includes an actuator mounted within the actuator housing and includes a clamp aperture disposed to receive the control link while the clamp aperture is being urged into an unclamped state by an opening force, the clamp aperture being operably configured to move between the unclamped state and a clamped state in response to the opening force being released, the aperture in the clamped state being operable to restrain the control link within the actuator for movement in a longitudinal direction substantially aligned with the elongate shaft.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Continuation Application of U.S. patentapplication Ser. No. 16/084,368, filed on Sep. 12, 2018, which is a U.S.National Stage Application filed under 35 U.S.C. § 371(a) ofInternational Patent Application No. PCT/CA2017/000056, filed Mar. 15,2017, which claims the benefit to U.S. Provisional Patent ApplicationNo. 62/308,296, filed Mar. 15, 2016, the entire disclosure of each ofwhich is incorporated by reference herein.

BACKGROUND 1. Field

This disclosure relates generally to surgical instruments and moreparticularly to a surgical instrument for laparoscopic or roboticsurgery.

2. Description of Related Art

Robotic surgical systems commonly employ one or more instrumentsassemblies that are manipulated by a robotic system to perform surgicaltasks. Each instrument is generally equipped with an end effector, suchas a surgical scissor, forceps, dissector, or other end effector forperforming specific operations. Commonly, the instrument is configuredwith a specific end effector and changing the end effector may requiresome disassembly of the instrument.

SUMMARY

In accordance with one disclosed aspect there is provided a surgicalinstrument apparatus for removably receiving an end effector coupled toan elongate control link for actuating the end effector to performsurgical operations. The apparatus includes an actuator housing and anelongate shaft extending from the actuator housing and having a bore forreceiving the control link. The apparatus also includes an actuatormounted within the actuator housing and includes a clamp aperturedisposed to receive the control link while the clamp aperture is beingurged into an unclamped state by an opening force, the clamp aperturebeing operably configured to move between the unclamped state and aclamped state in response to the opening force being released, theaperture in the clamped state being operable to restrain the controllink within the actuator for movement in a longitudinal directionsubstantially aligned with the elongate shaft.

The clamp aperture may include a channel for receiving the control link,and a clamp plate disposed to engage and exert a clamping force on thecontrol link when the aperture is in the clamped state, the clamp platebeing operable to resiliently deform in response to the opening forcecausing the clamp plate to disengage from the control link.

The clamp plate may be mounted to the actuator at a location distal tothe channel and may include a cantilevered length extending over thechannel, the cantilevered length of the clamp plate being configured toprovide the resilient deformation.

The cantilevered length may include a first cantilevered lengthextending beyond the channel, and a second cantilevered length in offsetrelation to the first cantilevered length and extending back over thechannel, the first and second cantilevered lengths configured to providethe resilient deformation.

The clamp plate may be mounted to the actuator using a compliantmounting that permits further resilient deflection of the clamp plateabout the compliant mounting.

The channel may include a material treated to increase friction forpreventing slippage of the control link within the channel when theaperture is in the clamped state.

The apparatus may include a clamp lever operable to provide the openingforce when in an open position.

The lever in the open position may protrude from the actuator housingand prevent loading of the surgical instrument into a driver forproviding drive forces to the actuator when the clamp aperture is in anopen state.

The actuator may include a longitudinally moveable portion housing theclamp aperture, a transversely movable portion for receiving a driveforce, and a coupling between the transversely moveable portion and thelongitudinally moveable portion, the coupling being operable to converttransverse movement of the transversely moveable portion intolongitudinal movement of the longitudinally moveable portion.

The apparatus may include a rotational actuator disposed within theactuator housing, and a torque tube enclosing the elongate control linkand extending through the bore of the elongate shaft, the torque tubebeing coupled to the rotational actuator and having a distal endoperable to couple to the end effector for causing rotation of the endeffector.

The rotational actuator may include a rotatable portion coupled to thetorque tube, and a transversely movable portion for receiving a driveforce, and a coupling between the transversely moveable portion and therotatable portion, the coupling being operable to convert transversemovement of the transversely moveable portion into rotation of therotatable portion and the torque tube.

The aperture may be located within a longitudinally moveable portion ofthe actuator and the actuator may further comprise a transverselymoveable portion, and a linkage extending between the transverselymoveable portion and the longitudinally moveable portion, the linkagebeing operably configured to translate transverse movement of thetransversely moveable portion into longitudinal movement of thelongitudinally moveable portion.

In accordance with another disclosed aspect there is provided an endeffector for use with the apparatus above, the control link of the endeffector having an open end operably configured to be received andclamped within the clamp aperture.

In accordance with another disclosed aspect there is provided a methodfor removably mounting an end effector in a surgical instrument, the endeffector being coupled to an elongate control link for actuating the endeffector to perform surgical operations. The method involves receivingthe control link within a bore of an elongate shaft extending from anactuator housing of the surgical instrument, the housing including anactuator mounted within the actuator housing for movement in alongitudinal direction substantially aligned with the elongate shaft.The method also involves receiving the control link in a clamp apertureof the actuator while the clamp aperture is being urged into anunclamped state by an opening force, and releasing the opening force tocause the clamp aperture to move between the unclamped state and aclamped state, the aperture in the clamped state being operable toimmobilize the control link within the actuator for causing longitudinalmovement of the control link.

Other aspects and features will become apparent to those ordinarilyskilled in the art upon review of the following description of specificdisclosed embodiments in conjunction with the accompanying figures.

BRIEF DESCRIPTION OF THE DRAWINGS

In drawings which illustrate disclosed embodiments,

FIG. 1 is a perspective view of a surgical instrument;

FIG. 2 is a perspective view of an end effector for use with thesurgical instrument shown in FIG. 1;

FIG. 3 is a perspective view of a portion of the surgical instrumentshown in FIG. 1 receiving the end effector shown in FIG. 2;

FIG. 4 is a cut away perspective view of a portion of an actuatorhousing of the surgical instrument shown in FIG. 1;

FIG. 5 is front perspective view of a longitudinal actuator and clampaperture in an open state;

FIG. 6 is a side view of the longitudinal actuator and clamp aperture inthe open state;

FIG. 7 is a front perspective view of the longitudinal actuator andclamp aperture in a closed state

FIG. 8 is a side perspective view of the longitudinal actuator shown inFIGS. 5-7;

FIG. 9 is a side perspective view of an alternative embodiment of thelongitudinal actuator;

FIG. 10 is a perspective view of an alternative embodiment of a clampplate for use in the longitudinal actuator shown in FIGS. 5-8.

DETAILED DESCRIPTION

Referring to FIG. 1, a surgical instrument apparatus in accordance withone disclosed embodiment is shown at 100. The surgical instrument 100includes an actuator housing 102 and an elongate shaft 104 extendingfrom the actuator housing. The actuator housing 102 houses a pluralityof transverse actuators 106 configured for transverse movement in adirection indicated by the arrow 108.

Referring to FIG. 2, a removable end effector for use with the surgicalinstrument 100 is shown at 110. The end effector 110 is coupled to anelongate control link 112 for actuating the end effector to performsurgical operations. In the example shown, the end effector 110 is ajawed instrument that is opened and closed in response to pushing andpulling movements of a proximate end 114 of the control link 112.

A portion of the surgical instrument 100 is shown in greater detail inFIG. 3 with the end effector 110 being inserted into the instrument.Referring to FIG. 3, in the embodiment shown the shaft 104 includes arigid portion 120 and an articulated portion 122. The articulatedportion 122 includes a plurality of coupled guides 124. A plurality ofcontrol links 126 (shown in part only in FIG. 3) extend back from thearticulated portion 122 to the actuator housing 102 and are coupled torespective transverse actuators 106 (shown in FIG. 1). In the embodimentshown, the eight transverse actuators 106 that are closest to theelongate shaft 104 are coupled to the plurality of control links 126while the transverse actuator 140 furthest away from the shaft 104actuates the control link 112 for operating the end effector 110. Thecoupled guides 124 are operable to move with respect to each other inresponse to pushing and/or pulling of the control links 126 causing adistal end 128 of the surgical instrument 100 to assume variouspositions and orientations. An articulated positioner is described indetail in commonly owned patent application PCT/CA2013/001076 entitled“ARTICULATED TOOL POSITIONER AND SYSTEM EMPLOYING SAME”, which isincorporated herein by reference in its entirety. A surgical instrumentand actuator housing is described in detail in commonly owned patentapplication PCT/CA2015/000098 entitled “ACTUATOR AND DRIVE FORMANIPULATING A TOOL”, which is incorporated herein by reference in itsentirety.

The shaft 104 has a bore 130 for receiving the control link 112, whichis threaded up through the bore toward the actuator housing 102. In thisparticular embodiment the bore 130 is centrally located and the controllink 112 is surrounded by the plurality of control links 126. Thecontrol links may be flexible nitinol wires capable of operation intension or compression without permanent deformation.

In the embodiment shown a torque tube 132 extends along the length ofthe bore 130 between the actuator housing 102 and the distal end 128 ofthe shaft 104. The torque tube 132 thus encloses the control link 112when the end effector 110 is received within the bore 130. The distalend 128 of the torque tube 132 is coupled to the end effector 110 via athreaded connection 116 and is able to rotate within the shaft 104 tocause a corresponding rotation of the end effector. The torque tube 132is rotated by movement of a transverse actuator 142 in the plurality oftransverse actuators 106.

A portion of the actuator housing 102 that houses the end effectoractuator and a rotational actuator for causing rotation of the torquetube 132 are shown in cut-away view in FIG. 4. Referring to FIG. 4, thetransverse actuator 140 is coupled to a longitudinally moveable actuatorportion 180 to form an end effector actuator 190. The longitudinalactuator 180 is slideably disposed on a shaft 182 for movement in alongitudinal direction indicated by the arrow 184. The longitudinalmovement direction 184 is substantially aligned with the shaft 104(shown in FIG. 1 and FIG. 3). In the embodiment shown the end effectoractuator 190 includes a coupling 186 that converts transverse movementof the transverse actuator 140 into longitudinal movement of thelongitudinal actuator 180. Transverse movement of the transverseactuator 140 causes corresponding transverse movement of the coupling186. The coupling 186 engages an angled slot 188 in the longitudinalactuator 180 and causes motion of the longitudinal actuator 180 alongthe shaft 182.

The surgical instrument 100 includes a rotational actuator 200 includinga rotational actuator portion 192 coupled via a coupling 194 to thetransverse actuator 142. The torque tube 132 is received within therotational actuator portion 192 and the coupling 194 converts transversemovement of the transverse actuator 142 into rotational movement forrotating the torque tube 132 and hence the end effector 110. In theembodiment shown the coupling 194 is implemented using a rack-and-pinionmechanism.

The longitudinal actuator 180 is shown in perspective view in FIG. 5 andin side view in FIG. 6. Referring to FIGS. 5 and 6, the longitudinalactuator 180 includes a clamp aperture 240 disposed to receive theproximate end 114 of the control link 112 while the clamp aperture isbeing urged into an unclamped state by an opening force. In FIGS. 5 and6 the clamp aperture 240 is shown in an open state ready for receivingthe control link 112. The clamp aperture 240 includes a channel 250 forreceiving the control link 112. The clamp aperture 240 is operablyconfigured to move between the unclamped state and a clamped state inresponse to the opening force being released. Referring to FIG. 7, thecontrol link 112 is shown received in the channel 250 of the clampaperture 240. The clamp aperture 240 is in a clamped state and operableto restrain the control link 112 within the actuator for movement of thelongitudinal actuator 180 on the shaft 182 in the longitudinal direction184.

In the embodiment shown in FIGS. 5-7, the clamp aperture 240 includes aresiliently deformable clamp plate 242, which is compliantly mounted onthe longitudinal actuator 180 and disposed to engage and exert aclamping force on the control link 112 when the aperture 240 is in theclamped state. An eccentric pin 244 actuated by a clamp lever 246provides an opening force that causes the clamp plate 242 to resilientlydeform (as best shown in FIG. 6) causing the clamp plate to disengagefrom the channel 250 to allow the control link 112 to be inserted. Whenthe opening force is released by moving the clamp lever 246 to positionshown in FIG. 7, the clamp plate 242 is resiliently urged into contactwith the control link 112 within the channel 250. In the clamped state,a clamping force is thus provided passively by the clamp plate 242 andthere is no tension on the clamp lever 246.

Referring to FIG. 8, the clamp plate 242 is mounted to the longitudinalactuator 180 at a location distal to the channel 250 and includes acantilevered length extending over the channel. The cantilevered lengthof the clamp plate is configured to provide the resilient deformation.Additionally, the clamp plate 242 is mounted to the longitudinalactuator 180 using a compliant mounting provided in this embodiment byBellville washers 260. The Bellville washers 260 are sandwiched betweena mounting plate 262 and the clamp plate 242 and the mounting plate isheld by a pair of screws 264 that are received in threaded holes (notshown) within the longitudinal actuator 180. The Bellville washers 260permit the clamp plate 242 to disengage from the channel 250 when anopening force is provided by the clamp lever 246 and the eccentric pin244. The retaining force provided by the clamp plate 242 may thus bepartly due to the resilience of the clamp plate 242 and partly due to aspring force exerted by the Bellville washers 260.

In one embodiment the channel 250 may be fabricated to increase frictionfor preventing slippage of the control link 112 within the channel whenthe aperture 242 is in the clamped state. For example, the channel 250may be formed using carbide inserts within the longitudinal actuator 180to increase the retaining force.

Referring to FIG. 9 an alternative clamp plate embodiment is shown at280. In this embodiment the clamp plate is provided by a stack ofcompliant clamp plates 282 mounted to a longitudinally moveable actuator284. The stack of compliant clamp plates 280 are fastened to thelongitudinal actuator 284 using a pair of screws 286 received inthreaded holes (not shown) within the longitudinal actuator. A lowerclamp plate 288 in the stack of compliant clamp plates 280 engages theeccentric pin 244 and the stack of plates operate together to providethe retaining force.

Referring to FIG. 10, another alternative embodiment of the clamp plateis shown at 300. The clamp plate 300 has a first cantilevered length 302that extends beyond the control link 112 in the channel 250 (shown inbroken lines). The clamp plate 300 also has a second cantilevered length304 in offset relation to the first cantilevered length 302 andextending back over the channel 250. The first and second cantileveredlengths 302 and 304 provide for a greater resilient deformation than theclamp plate 242 shown in the previously disclosed embodiments.

Referring back to FIG. 4, the clamp lever 246 is shown in the clampedposition corresponding to the clamped state shown in FIG. 7 and thelever aligns with the back of the housing. When the lever 246 is openedto place the clamp aperture 240 in the open state (shown in FIG. 5), thelever will thus protrude from the actuator housing 102. When thesurgical instrument 100 is received within a surgical system (not shown)the protruding lever may prevent loading of the surgical instrumentwhile the clamp aperture 240 is open. This provides an additional levelof safety that prevents an unclamped end effector 110 from being used inthe surgical system, which could cause significant problems during asurgery.

The above disclosed embodiments provide for quick loading and unloadingof the end effector 110 and thus facilitate use of different endeffectors with the surgical instrument 100. The clamp aperture 240 thusfacilitates quick loading of different end effectors into the surgicalinstrument 100. Additionally, the resiliently deformable clamp plate 242permits the clamp aperture 240 to function over a fairly large toleranceband for clamping different end effectors.

The disclosed embodiments allow a disposable end effector 110 to bequickly and easily mounted on the surgical instrument 100. Typically,the end effector 110 would be mounted on a sterilized instrument 100prior to the commencement of the surgery. Once the surgery is completedthe end effector 100 may be removed, which has the advantage ofpotentially reducing risk of infection since the contaminated endeffector that was in contact with tissue during the procedure may bediscarded. A new sterilized end effector 100 would then be used for thenext procedure. The instrument 100 may be cleaned and sterilized forre-use, usually for a pre-determined number of uses. Removal of the endeffector 110 prior to cleaning and sterilization simplifies cleaning ofthe surgical instrument 100 since there are less parts to clean and thebore 130 is open during cleaning for flushing out the any accumulateddebris such as blood and tissue that may have accumulated during theprocedure.

While specific embodiments have been described and illustrated, suchembodiments should be considered illustrative of the invention only andnot as limiting the invention as construed in accordance with theaccompanying claims.

What is claimed is:
 1. A surgical instrument apparatus for removablyreceiving an end effector coupled to an elongate control link foractuating the end effector to perform surgical operations, the apparatuscomprising: an elongate shaft defining a bore for receiving the controllink; and an actuator including: a longitudinally movable portiondefining a clamp aperture, wherein the clamp aperture has a clampedstate and an unclamped state, wherein the actuator is operablyconfigured to move the clamp aperture between the unclamped state andthe clamped state in response to an opening force being released fromthe actuator, wherein the clamp aperture is configured to: receive thecontrol link within the actuator while the clamp aperture is being urgedinto the unclamped state by the opening force; and restrain the controllink within the actuator, for movement in a longitudinal directionsubstantially aligned with the elongate shaft, while the clamp apertureis in the clamped state; a transversely movable portion for receiving adrive force; and a coupling disposed between the longitudinally movableportion and the transversely movable portion, the coupling beingoperable to convert transverse movement of the transversely movableportion into longitudinal movement of the longitudinally movableportion.
 2. The apparatus of claim 1, wherein the clamp aperturecomprises: a channel for receiving the control link; and a clamp platedisposed to engage and exert a clamping force on the control link whenthe clamp aperture is in the clamped state, the clamp plate beingoperable to resiliently deform in response to the opening force causingthe clamp plate to disengage from the control link.
 3. The apparatus ofclaim 2, wherein the clamp plate is mounted to the actuator at alocation distal to the channel and includes a cantilevered lengthextending over the channel, the cantilevered length of the clamp plateis configured to provide the resilient deformation.
 4. The apparatus ofclaim 3, wherein the cantilevered length comprises: a first cantileveredlength extending beyond the channel; and a second cantilevered length inoffset relation to the first cantilevered length and extending back overthe channel, the first and second cantilevered lengths configured toprovide the resilient deformation.
 5. The apparatus of claim 3, whereinthe clamp plate is mounted to the actuator using a compliant mountingthat permits further resilient deformation of the clamp plate about thecompliant mounting.
 6. The apparatus of claim 2, wherein the channelincludes a material treated to increase friction for preventing slippageof the control link within the channel when the clamp aperture is in theclamped state.
 7. The apparatus of claim 1, further comprising a clamplever operable to provide the opening force when in an open positionthereof.
 8. The apparatus of claim 7 further comprising: an actuatorhousing, wherein the elongate shaft extends from the actuator housing,and wherein the actuator is mounted within the actuator housing.
 9. Theapparatus of claim 8 wherein the clamp lever in the open positionprotrudes from the actuator housing and prevents loading of the surgicalinstrument apparatus into a driver for providing drive forces to theactuator when the clamp aperture is in an open state.
 10. The apparatusof claim 8, further comprising: a rotational actuator disposed withinthe actuator housing; and a torque tube enclosing the elongate controllink and extending through the bore of the elongate shaft, the torquetube being coupled to the rotational actuator and having a distal endoperable to couple to the end effector for causing rotation of the endeffector.
 11. The apparatus of claim 10, wherein the rotational actuatorincludes: a rotatable portion coupled to the torque tube; a transverselymovable portion for receiving a drive force; and a coupling between thetransversely movable portion and the rotatable portion of the actuator,the coupling being operable to convert transverse movement of thetransversely movable portion into rotation of the rotatable portion andthe torque tube.
 12. A surgical instrument apparatus for removablyreceiving an end effector coupled to an elongate control link foractuating the end effector to perform surgical operations, the apparatuscomprising: an elongate shaft defining a bore for receiving the controllink; and an actuator including: a longitudinally movable portion; aclamp aperture disposed to receive the control link while the clampaperture is being urged into an unclamped state by an opening force, theclamp aperture being operably configured to move between the unclampedstate and a clamped state in response to the opening force beingreleased, the clamp aperture in the clamped state being operable torestrain the control link within the actuator for movement in alongitudinal direction substantially aligned with the elongate shaft,wherein the clamp aperture is located within the longitudinally moveableportion of the actuator; a transversely moveable portion; and a linkageextending between the transversely moveable portion and thelongitudinally moveable portion, the linkage being operably configuredto translate transverse movement of the transversely moveable portioninto longitudinal movement of the longitudinally moveable portion. 13.The apparatus of claim 12, further comprising an actuator housing,wherein the elongate shaft extends from the actuator housing.
 14. Asurgical instrument apparatus, comprising: an end effector coupled to anelongate control link for actuating the end effector to perform surgicaloperations; an elongate shaft defining a bore for removably receivingthe control link therethrough and for supporting the end effector at adistal end thereof; and an actuator including: a longitudinally movableportion; a clamp aperture disposed to receive the control link while theclamp aperture is being urged into an unclamped state by an openingforce, the clamp aperture being operably configured to move between theunclamped state and a clamped state in response to the opening forcebeing released, the clamp aperture in the clamped state being operableto restrain the control link within the actuator for movement in alongitudinal direction substantially aligned with the elongate shaft,wherein the clamp aperture is located within the longitudinally moveableportion of the actuator; a transversely moveable portion; and a linkageextending between the transversely moveable portion and thelongitudinally moveable portion, the linkage being operably configuredto translate transverse movement of the transversely moveable portioninto longitudinal movement of the longitudinally moveable portion. 15.The apparatus of claim 14, further comprising an actuator housing,wherein the elongate shaft extends from the actuator housing.
 16. Theapparatus of claim 14, wherein the control link defines an open endoperably configured to be received and clamped within the clampaperture.